主链含有非共轭结构的聚芴类蓝光聚合物的合成与性能研究

通过Suzuki偶合反应合成出了主链中含有非共轭烷氧基组分(-O-CH2-CH2-CH2-CH2-O-)的聚芴类衍生物聚- 2,7-(9,9-二辛基芴)-co-4,4’-丁氧基二苯(PFP)和聚-2,7-(9,9-二辛基芴)-co-4,4’-丁氧基二苯-co-N-苯基-4,4’-二苯胺(PFTP11)并通过相同的条件合成出主链由芴和三苯胺交替相连的聚合物聚-2,7-(9,9-二辛基芴)-co-N-苯基-4,4’-二苯胺(PFTPA)作为参比材料. 通过1H NMR和FT-IR分析对这些聚合物的化学结构进行了表征. 这三种聚合物在常用的有机溶剂中具有很好的溶解性, 可通过溶液加工的方式制备聚合物薄膜. 这些聚合物均具有较高的热分解温度(＞400 ℃), 聚合物PFP具有较高的玻璃化转变温度(～130 ℃)而PFTP11和PFTPA则未出现明显的玻璃化转变过程. 通过对聚合物的吸收特性进行测试得知它们具有较大的光学带宽(2.89～3.29 eV). 所有聚合物在固体薄膜状态下均发射出蓝色荧光, PFP, PFTP11和PFTPA的最大PL发射分别位于425, 437和440 nm. 通过对其电化学性能进行测试可知由于三苯胺基团的引入聚合物的HOMO能级明显提高, 这意味着聚合物的空穴传输能力得到了有效的改善.     

胺烷基侧链取代三苯胺类红光聚合物的合成及性能研究

通过Suzuki偶合反应合成了一系列胺烷基侧链取代的基于三苯胺和芴的共轭聚合物聚[4-(N,N-二甲基胺丙氧基)苯-4,4′-二苯胺-9,9-二辛基芴-4,7-二噻吩-2-基-2,1,3-苯并噻二唑](PFTD), 并对其化学结构和光电性能进行了表征. 末端胺基的存在提高了此类聚合物作为发光层应用于聚合物电致发光器件的性能(采用高功函数的金属铝作为阴极时). 结构为ITO/PVK/PFTD-5(DBT摩尔分数为5%时的聚合物)/Al的器件最大电致发射峰位于647 nm, 最大外量子效率达到了1.24%.     

磺酸盐取代三苯胺类共轭聚电解质的合成及应用研究

通过水相Suzuki偶合反应合成了两种磺酸盐基团取代的三苯胺类共轭聚电解质PTP11和PTP31,对其化学结构进行了表征.通过对其光学和电化学性能进行测试得知,此类聚合物具有和ITO功函数相近的HOMO能级及较高的LUMO能级.磺酸盐基团的存在使得此类聚电解质具有和电中性聚合物所不同的溶解性,当其作为空穴传输材料应用于多层结构的聚合物电致发光器件(PLED)中时,可有效避免空穴传输层-发光层之间的界面混溶问题.以这两种聚合物作为空穴传输材料应用于以PFO-DBT15为发光层的红光PLEDs中时,器件的性能得到了显著提高.此外,磺酸盐基团的不同取代方式会对器件的性能产生一定的影响.     

含有萘并噻二唑的红光电致发光聚合物的合成和性能研究

以2,7-二溴-9,9-双(N,N-二甲基丙胺基)芴与4,7-双(5-溴-2-噻吩)-2,1,3-萘并噻二唑为共聚单体, 通过Suzuki偶合反应合成按不同比例共聚的一系列共轭聚合物, 并对它们的电致发光性能进行了研究. 结果表明, 所有的聚合物均在高功函数金属铝作阴极的器件中具有较高的发光效率, 最大电致发光外量子效率为1.3%, 好于目前广泛应用的低功函数金属(如钡, 钙等)作阴极的发光效率.     

高度可溶聚苝酰亚胺材料的合成及性能研究

聚酰亚胺是一类具有优异综合性能的聚合物材料 [1,2 ] .近年来 ,合成含荧光染料的可溶性聚酰亚胺材料在聚合物化学领域引起了广泛兴趣 [3～ 11] ,人们期望这类聚合物材料会比其小分子材料具有更加优越的性能 .小分子酰亚胺荧光染料具有极高的荧光量子效率、光化学和热稳定性 ,可广泛应用于光学开关[12 ] 、电致发光器件 [13,14 ] 和太阳能转换器 [15] 等领域 ,但是由于的大π键平面共轭结构 ,使得材料的溶解性能极差 ,难以加工 .最近 ,本实验室通过合成含叔丁基的芳香二胺 [4,4′-亚甲基双 ( 2 -叔丁基苯胺 ) ]与各种芳香四酸二酐反应…     

含三苯胺单元的超支化共轭聚合物的合成、表征及应用

本实验采用Wittig方法制得了未封端和封端的超支化聚三苯胺-对苯乙烯撑型聚合物,对两种共轭聚合物进行了表征和性能测试.聚合物溶液和固体膜在紫外光照射下均发出较强的绿光.首次对这类聚合物在硝基芳烃化合物荧光猝灭能力进行了初步研究,结果表明:与未封端产物相比,封端后的超支化共轭聚合物在邻硝基甲苯(o-NT)的荧光猝灭效率上有明显提高,当o-NT浓度为21.5×10^-3mol/L时,荧光猝灭效率达到97%.这类共轭聚合物不仅合成操作较为简便,猝灭效率也较高,是一种很有潜力的硝基芳烃化合物荧光检测材料.     

含二乙炔类共轭聚合物的合成及性能研究

在以CuCl和四甲基乙二胺(TMEDA)作为催化剂和邻二氯苯作溶剂条件下,以二-(4-乙炔苯基)-4-辛氧基苯胺(M1)和3, 6-双(乙炔基)-N-辛基咔唑(M2)作为单体,通过Glaser-Hay氧化偶联反应合成了含有咔唑和三苯胺结构单元的聚芳烃二乙炔共轭聚合物.采用红外光谱、核磁共振谱、热失重分析、紫外吸收光谱和荧光光谱等方法对聚合物进行结构表征与性能测试.所得到的聚合物都溶于普通的有机溶剂(如四氢呋喃、二氯甲烷、氯仿、甲苯等).结果表明,聚合物具有优异的热稳定性,热失重5 %时,分解温度在400℃以上;在光激发的条件下,聚合物在二氯甲烷溶液中发射蓝光.     

聚合物光电功能材料的合成与器件探索

在本实验室以前工作的基础上,利用Wittig反应和Wittig-Horner反应,合成了含有三苯胺单元的交替共聚物,它们具有良好的溶解性、成膜性和热稳定性,是一类具有较高效率的发绿光材料.通过在聚合物中引入芴和联苯的结构以及在PPV单元上引入不同链长的侧基等,研究了聚合物的几何构型以及位阻等因素对材料性质的影响.通过三元共聚研究了聚合物链中三苯胺含量对发光性能的影响,其中以三苯胺、PPV和二甲氧基PPV组成的三元共聚物在聚合物LED中得到了良好的电致发光性能.     

含三苯胺单元的共轭聚合物的合成、表征及应用

采用 Wittig 方法制得了未封端及封端的线性聚三苯胺-对苯乙烯撑型聚合物(分别简称为:TPA-DOPPV1,TPA-DOPPV2),并对共轭聚合物进行了表征和性能测试.封端后的聚合物溶液和固体膜在紫外光照射下均发出较强的绿光.对这类聚合物在硝基化合物检测方面的应用进行了初步研究,结果表明:封端后的共轭聚合物在邻硝基甲苯(o-NT)荧光检测上的性能明显提高,当o-NT 浓度为 21.5×10-3 mol/L 时,荧光猝灭效果达到了 96%;在2,4-二硝基甲苯(DNT)、对硝基甲苯(P-NT)和对苯醌(p-BQ)蒸汽中放置 10 s 时,其薄膜的荧光猝灭效率分别达到 30%、15.6%和 3.1%.TPA-DOPPV2 的合成操作较为简便,具有一定的检测灵敏性,是一种潜在的硝基类爆炸物荧光检测材料.     

功能化改性聚硅烷的研究进展及应用前景

聚硅烷是一类主链由连续Si原子组成的聚合物,其主链具有类似于大π共轭的σ-σ共轭结构.这种特殊结构使得线型聚硅烷既具有与普通大π共轭导电聚合物相似的电导行为,又具有其它导电聚合物所不具备的优良溶解性和可加工性,是一类潜力巨大的功能高分子材料.但单纯聚硅烷的光致/电致发光和导电性能与其它功能高分子材料相比还不够突出,自身对水分和空气比较敏感,需要对其进行改性.本文对聚硅烷的结构与性能之间的关系进行了归纳,对聚硅烷的改性方法进行了详细分类并综述,并对聚硅烷的应用方向和研究进展进行了总结,最后对功能化聚硅烷的应用前景进行了展望.     

2-甲基-8-羟基喹啉-丙烯酸-镓(Ⅲ)与甲基丙烯酸甲酯共聚物的合成与表征

制备了 2 甲基 8 羟基喹啉、丙烯酸与镓 (Ⅲ )的三元配合物 ,将此配合物与甲基丙烯酸甲酯共聚后得到含镓 (Ⅲ )的共聚物 ,这种共聚物易溶于氯仿、丙酮等普通低沸点溶剂 ,具有良好的成膜性能 .用红外光谱、元素分析、紫外光谱等方法对三元配合物和共聚物的组成进行了表征 .测试三元配合物和共聚物的荧光光谱 ,表明共聚物在 4 96nm处能发出较强的荧光 .DSC和TG分析表明 ,共聚物具有良好的耐热性和热稳定性 .     

Bipolar copoly(aryl ether) containing distyrylbenzene,triphenylamine, and 1,2,4‐triazole moieties: Synthesis and optoelectronic properties

A novel copoly(aryl ether) ( P1 ) consisting of alternate emitting segments (distyrylbenzene) and a bipolar moiety composed of directly linked electron‐transporting aromatic 1,2,4‐triazole and hole‐transporting triphenylamine was synthesized. The copoly(aryl ether) is readily soluble in common organic solvents and exhibit good thermal stability with thermal decomposition temperature above 450 °C. The emission and the photoluminescence quantum yield of the copolymer are dominated by the emitting segments (distyrylbenzene) with longer emissive wavelength. Electron affinity of P1 is evidently enhanced after introducing the isolated bipolar unit, as confirmed by the lowered lowest unoccupied molecular orbital level (–2.77 eV) relative to P0 without bipolar unit (–2.34 eV). This results in improved emission efficiency of its polymer light‐emitting diode (indium tin oxide/poly(3,4‐ethylene dioxythiophene):poly(styrene sulfonate)/ P1 /LiF/Ca/Al) due to more balanced charges injection and transport. Blending P1 with poly(9,9‐dihexylfluorene) ( PF ) further improves the efficiency of the device; the best performance was obtained for PF / P1 = 20/0.8 (w/w) with maximum luminance and maximum luminance efficiency being significantly enhanced to 3260 cd/m² and 1.08 cd/A, respectively, from 380 cd/m² and 0.009 cd/A of P1 ‐based device. These results demonstrate that the bipolar moiety can be used to enhance charges injection and transport of electroluminescent polymers. © 2011 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2011     

铝试剂的荧光光谱与荧光量子产率

首次研究了铝试剂的荧光光谱和荧光量子产率,发现pH3至pH12条件下,用紫外光照射铝试剂溶液可以产生荧光,最大激发波长和最大发射波长分别为297nm和409nm,荧光强度与铝试剂浓度之间存在良好的线性关系,线性范围为0.01～3μg/mL,检测下限为0.01μg/mL,以硫酸奎宁为参比,测得铝试剂的荧光量子产率为0.16。     

Synthesis of an electroluminescent polymer and its non‐doped light‐emitting diodes with stable green emission

An electroluminescent polymer was synthesized by Wittig condensation and characterized by the measurements of ¹H‐NMR, IR, gel permeation chromatography (GPC), UV–Vis, PL, and cyclic voltammetry (CV). The polymer can be dissolved in common organic solvents such as tetrahydrofuran (THF), chloroform, and dichloromethane. The electroluminescent investigation showed that the non‐doped devices with a double‐layer configuration (ITO/PEDOT:PSS/Polymer/Mg:Ag) have a stable green emission property. The maximum luminance of the annealed device reaches 2317 cd/m². The emission maximum and the CIE 1931 coordinate values are respectively stabilized at 552 nm and near (x, y) = (0.43, 0.55) with different voltages. Copyright © 2008 John Wiley & Sons, Ltd.     

Rational Design of a Near-infrared Fluorescent Material with High Solid-state Efficiency,Aggregation-induced Emission and Live Cell Imaging Property

Near-infrared(NIR) fluorescent materials with high photoluminescent quantum yields(PLQYs) have wide application prospects. Therefore, we design and synthesize a D-A type NIR organic molecule, TPATHCNE, in which triphenylamine and thiophene are utilized as the donors and fumaronitrile is applied as the acceptor. We systematically investigate its molecular structure and photophysical property. TPATHCNE shows high T_gof 110℃ and T_d of 385℃ and displays an aggregation-induced emission(AIE) property. A narrow optical bandgap of 1.65 eV is obtained. The non-doped film of TPATHCNE exhibits a high PLQY of 40.3% with an emission peak at 732 nm, which is among the best values of NIR emitters. When TPATHCNE is applied in organic light-emitting diode(OLED), the electroluminescent peak is located at 716 nm with a maximum external quantum efficiency of 0.83%. With the potential in cell imaging, the polystyrene maleic anhydride(PMSA) modified TPATHCNE nanoparticles(NPs) emit strong fluorescence when labeling HeLa cancer cells, suggesting that TPATHCNE can be used as a fluorescent carrier for specific staining or drug delivery for cellular imaging. TPATHCNE NPs fabricated by bovine serum protein(BSA) are cultivated with mononuclear yeast cells, and the intense intracellular red fluorescence indicates that it can be adopted as a specific stain for imaging.     

Synthesis and characterization of a high-efficiency light-emitting alternating copolymer

A new high-efficiency light-emitting alternating copolymer of triphenylamine and pure PPV (TPA–PPV) has been designed and synthesized. The copolymer was highly soluble in common solvents. It could be spin cast onto various substrates to give highly transparent homogeneous thin films without heat treatment. The fluorescence quantum yield in benzene is almost up to 1.00. The maximum fluorescence wavelength for this alternating copolymer appeared around 470 nm. The fluorescence of TPA–PPV solution quenched by C₆₀ was examined, and the result indicated that a strong interaction exists between TPA–PPV and C₆₀ at the exited state. A primary single-layer LED based on ITO/TPA–PPV/Al has been fabricated, and the onset voltage is only 1.5 V and a bright green light was observed. The electroluminescence spectrum gives a peak at 510 nm when the operating voltage of 17 V was applied. The photoluminescence spectrum also appeared at the same wavelength as the electroluminescence, indicating that the same excited states are involved in the two processes. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 2587–2594, 1999     

Synthesis, Crystal Structure and Properties of 2,7-Bis [4-（diphenylamino）phenyl] fluorene

A novel fluorene derivative containing triphenylamine groups, 2,7-bis[4-(diphenylamino)-phenyl]fluorene (C49H36N2 , Mr= 652.80), was synthesized via Suzuki coupling reaction (yield: 19%) and its crystal structure was determined by single-crystal X-ray diffraction. It crystallizes in triclinic, space group P1 with a = 9.320(4), b = 11.250(6), c = 17.369(6) , α = 88.035(3), β = 86.450(5), γ = 73.524(5)°, V = 1742.8(13) 3 , Z = 2, Dc = 1.244 g/cm 3 , μ(MoKα) = 0.072 mm -1 , F(000) = 688, S = 1.095, the final R = 0.0616 and wR = 0.1878. It presents a linear framework constituted by a linkage of fluorene as a bridge and two triphenylamine groups. Its spectral and electrochemical properties were studied by UV-Vis absorption, fluorescence spectroscopy and cyclic voltammetry (CV). This compound can emit intense blue fluorescence with a peak wavelength of 446 nm and a full width at half maximum (FWHM) of 38 nm under UV excitation at 350 nm in film. The highest occupied molecular orbital (HOMO) energy level, the lowest unoccupied molecular orbital (LUMO) energy level and optical band gap (Eg) of the title compound are -5.46, -2.57 and 2.89 eV, respectively.     

铽-依诺沙星-SDS敏化荧光猝灭法检测雷公藤红素

在pH 9.3的氨-氯化铵缓冲溶液中,铽(Ⅲ)能与依诺沙星、十二烷基硫酸钠(SDS)形成荧光配合物(λex=330 nm、λem=545 nm),SDS的存在能增强配合物的荧光强度。研究发现,在该反应体系中加入适量雷公藤红素溶液后,铽(Ⅲ)与依诺沙星络合物的激发、发射峰位置不变,但其荧光强度呈规律性下降。据此,建立了简单、快速、灵敏地测定雷公藤红素的荧光分析方法。雷公藤红素的浓度在5.2×10-6～8.4×10-5 mol/L范围内呈良好线性关系,方法的检出限为4.1×10-8 mol/L。     

含吡啶环的芳香醚-噁二唑类化合物的合成及其光谱研究

为开发新的高强度的有机电致发光材料, 用含烷氧基的取代苯甲酸(2)与2,6-吡啶二甲酰肼(3)在POCl3作用下, “一锅煮”法合成6个结构对称的含吡啶环的芳香醚-噁二唑4a～4f. 通过MS, IR, 1H NMR, 元素分析等手段对其结构进行了表征. 化合物的荧光性能测定结果显示此类化合物具有良好的荧光性, 其荧光发射波长均在347～507 nm范围内, 最大荧光发射波长在384 nm附近处, 且荧光强度较强. 在芳环上引入5-Br基团(4e, 4f), 化合物的荧光发射波长发生红移, 荧光强度有所减弱. 以硫酸奎宁作参比, 测定6个目标产物的荧光量子产率, 5-Br基团的引入对荧光量子产率没有明显影响. 同时讨论了代表性产物4a在不同溶剂中最大荧光激发波长处的荧光量子产率, 发现溶剂极性对该类化合物的荧光量子产率基本没有影响.     

苯基取代聚苯撑乙烯的合成及其电致发光性能

聚苯撑乙烯(PPV)类聚合物是优异的发光材料, 有望作为全色显示中三基色的材料之一得到应用. 我们采用2-溴-1,4-亚二甲苯二乙酯为原料, 合成了商品名为Supper Yellow PPV (SY PPV)的苯基取代PPV. 中间体、单体和聚合物的结构都通过核磁共振、元素分析进行了表征. SY PPV的吸收峰在434 nm, 吸收边在510 nm, 带隙2.44 eV. 光致发光峰值和电致发光峰值分别在516和552 nm. SY PPV的器件性能为: 启动电压为2.4 V, 最大亮度大于49000 cd·m^-2, 最大流明效率为21 cd·A^-1, 显著优于采用老方法合成SY PPV的最大流明效率(16-18 cd·A^-1).